Intro to Musical Acoustics
A Brief Introduction to Musical Acoustics
EE477 R.C. Maher Spring 2006 Harmonic and Inharmonic Sounds
• Musical instruments with simple oscillators usually produce periodic waveforms • Periodic waveforms have a fundamental frequency, f0, and a harmonic spectrum: spectral energy just at frequencies that are integer multiples of f0. • These harmonic components are called harmonics, overtones, or partials . • Some musical instruments produce inharmonic sounds: bells, drums, etc.
2 Pitch
•Musical sounds often have a pitch that is related to the sound’s spectral content •The pitch of a harmonic sound is usually close to the fundamental frequency of that sound •Inharmonic sounds may have a perceived pitch, but it is not merely the fundamental of some harmonic series
3 Organization of Western Music
•Two harmonic sounds with different fundamental frequencies can lead to interesting frequency coincidences among their partials •When the fundamentals have a low integer ratio relationship, this is a consonant interval
4 Consonant Intervals
Unison 3rd 4th 5th Octave 1/1 5/4 4/3 3/2 2/1 100 125 133.33 150 200 200 250 266.67 300 400 300 375 400 450 600 400 500 533.33 600 800 500 625 666.67 750 1000 600 750 800 900 1200 700 875 933.33 1050 1400 800 1000 1066.67 1200 1600 900 1125 1200 1350 1800 1000 1250 1333.33 1500 2000 1100 1375 1466.67 1650 2200 1200 1500 1600 1800 2400 1300 1625 1733.33 1950 2600 1400 1750 1866.67 2100 2800 1500 1875 2000 2250 3000 1600 2000 2133.33 2400 3200 5 Musical Scales and Temperament
•European music is based on the notion of a diatonic pitch scale. The scale specifies the allowable musical pitches: 8 scale steps out of 12. •Problem: if integer frequency ratios are used (Just intonation), chords only sound in tune if based on fundamental (tonic) pitch. Changing musical “key”is not possible.
6 Equal Tempered Scale
•To solve the musical “key”problem, keyboard instruments now use equal- tempered tuning. •Note frequencies are distributed uniformly in a logarithmic span: n/12 fn = f0 ´ 2 •Just vs. equal tempered tuning:
Unison 3rd 4th 5th Octave 100 125.0000 133.3333 150.0000 200.0000 100 125.9921 133.4840 149.8307 200.0000 7 Rhythm
•Beats per minute •Beats per measure (time signature) •Duration of musical notes specified in fractions: whole, half, quarter, eighth, sixteenth, 32nd
8 Musical Notation
•Notation specifies pitches, durations, and time evolution •Representation is like a spectrogram: frequency vs. time
9 Standard Tuning Frequencies
“middle C”
l § 78cm l § 33cm l § 5.2m l § 2.6m l § 1.3m l § 66cm C6 1046.5Hz C2 65.41Hz C4 261.62Hz C5 523.25Hz C3 130.81Hz A4 440Hz
10 Musical Timbre
•The relative spectral energy at different frequencies is perceived as a distinct tone color, or timbre (pronounced as either tam- -burr or tim-burr) •Timbre: The combination of qualities of a sound that distinguishes it from other sounds of the same pitch and volume
11 Musical Instruments
•Almost any object can be considered a musical instrument •Most conventional musical instruments have –an excitation source –avibrating element –aresonant body –a means of coupling the vibrations so that they radiate into the air as sound waves
12 Musical Instruments (cont.)
•The excitation is a motive force •The vibrating element usually creates many harmonics •The resonant body emphasizes some frequencies and deemphasizes others •The coupling means takes energy from the vibrating element and “loses”it (radiates) into an acoustical wave through the air
13 Example: Singing Voice
Projection from the mouth
Resonance of the throat, nasal passages, and the mouth
Glottis (vocal cords)
Lungs
14 Example: String Instrument
Bow or pluck excitation. Vibrating string couples energy to the hollow wood body (resonator). Vibrating body couples sound into the air (radiation).
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